DE2812408A1 - AUTOMATIC CABLE EQUALIZATION - Google Patents

Description

12408

ECA 71 770 Ks / Iw, - ^ T ^ isa ^

'' Uf. Dieter v. Bezoldl ^

Brit. Serial No: 11903/77 Dfpl.-Ir.g. F ^ "he Schute

Filed: March 21, 1977 Dlpl.-ing. Wolfgang Heusler

S Eüiünchen 8a, Fostrsch 8606SS

ECA Corporation
Hew York, N ₀ To, V ₀ St ₀ v "A <

Automatic cable equalization circuit

The invention relates to cable equalization circuits, with which the "distorting influence of cable attenuation control = Compensate losses on signals transmitted through a cable · = The invention relates specifically to an automatic cable eliminator for equalizing video signals from a television camera,

If you transmit video signals Z ₀ B ₀ from television cameras that are located in distant or widely spaced locations, then the attenuating influence of the transmitting cable on the video signal is often so noticeable that corrective measures are necessary ₉ to control the signal to be processed O Cable losses can generally be divided into two categories, namely ohmic losses and capacitive or dielectric losses _o The first category, which is due to the effective resistance of the cable, causes relatively linear attenuation over the frequency range of the transmitted signal and generally does not cause any major concern _o More problematic, however, are the losses attributable to the capacity of the cable ₂ "

809839 / 094S

since their influence is "the higher frequencies of the to attenuate the transmitted signal. The problem of cable attenuation the signal becomes even larger when the length of the cable is changed, as is often the case when Switching between video signal sources that are at different distances from the central processing Facility "are located. Since a fixed cable equalization of the proportions Typical television cable installations are not sufficient, it is general Bcaxis that the received signal is based on a waveform control device and manually switch on cable equalization circuits, e.g. networks to raise the high frequencies to compensate for the high frequency losses occurring in the cable.

With the invention, a cable equalization circuit is created, automatically to signals that are transmitted through a cable and suffer losses in amplitude and frequency response to rectify. The circuit contains a device for adding a reference signal to the signal to be transmitted insert that contains both low-frequency components and high-frequency components between which there are an amplitude difference as a result of transmission losses adjusts. A signal summing circuit is also provided which is responsive to the cable signals to produce an output signal to deliver. A signal processing circuit is coupled to the cable signals to process one of the cable signals generate derived correction signal. With the signal summing circuit a detector is coupled to develop a control signal proportional to the relative Amplitude difference between the low-frequency and high-frequency components of the reference signal. One on the correction signal and responsive to the control signal multiplier circuit ensures that a through the control signal certain amount of the correction signal on the signal

809839/0946

nalsummizing circuit is given to the amplitude of the Restore output s signal s.

The invention is explained in more detail below using an exemplary embodiment with reference to drawings.

FIG. 1 shows a block diagram of an automatic device according to the invention Cable equalization circuit;

FIGS. 2a and 2b show waveforms to aid in understanding the operation of the drawing shown in FIG facilitate.

According to Figure 1, a video signal (video input), for example from a television camera, coupled to the transmitting end of a cable 10. In the drawing is the cable 10 shown in indefinite length, typical cable installations may cable lengths of one or a few Meters to 300 meters or more included. The signal at the output of the cable 10 is applied to the input terminals of a Amplifier 12 coupled. The amplifier 12 is a design known as a differential amplifier, which is why it is special is advantageous because it can suppress common-mode signals such as thimble caused in the cable and because it can deliver two identical output signals, whose first via a resistor 14 to the input of a summing output s amplifier circuit is coupled, which consists of a Amplifier 18, the input resistors 14, 20 and one Feedback resistor 16 exists. The output terminal of the output amplifier is well suited as a connection (video output), from which the video signal from the cable to others Video signal processing equipment (not shown) can be coupled. The other output signal from the input amplifier 12 is raised to a high frequency

809839/0946

-ix

Network 26 coupled -and also fed to a stage 28, the circuits for separating deflection sync pulses and color sync pulses (burst) and for generating burst gate pulses contains. The high frequency boosting network 26 produces an output signal corresponding to its input supplied input signal is complementary, i.e. the frequency response of the amplitude of this output signal increases with increasing frequency of the input signal, so that an output signal is supplied whose amplitude increases when the frequency of the input signal increases. The parameters of the network 26 are selected so that that caused by the network The amplitude increase is opposite and equal (i.e. complementary) to the attenuation that the video signal during its transmission over the cable 10 learns. The output signal of the network 26 is applied to an input (Σ) of a multiplier circuit 24- given, which can e.g. be an integrated module of the Motorola MC-1595 type. The outcome of the Multiplier circuit 24 · is via the resistor 20 to a second input of the signal-summing output amplifier 18 coupled. The other input (Y) of the multiplier circuit 24 is supplied with a control signal which is in the is produced according to the invention and to be described below manner, and which serves that portion of the above to determine the complementary corrected signal described, the attenuated input signal at the input of the Output amplifier is to be added. The attenuated video signal coming from cable 10 therefore appears at the output of the amplifier, after a correction signal has been added to it, which is equal to and opposite to the signal attenuation is caused during the transmission via the cable 10, so that a video signal is supplied at the video output becomes, in.dem the amplitude of the output signal is equal is the original signal applied to the input end of the cable 10. , _

809839/0946

The control signal for the Y input of the multiplier circuit 24- is generated in the following way. A reference signal is inserted into the signal to be transmitted through the cable, which serves as a yardstick for the losses caused during the transfer. In the example shown, where the transmitted signal is a television signal, the reference signal can easily be in the horizontal blanking interval to be inserted; Basically, however, it is possible to transfer the reference signal to any point in the Insert signal. Since the reference signal is contained in the signal to be transmitted, it must have a form that upon arrival at the receiving end of the cable information about the total experienced signal attenuation as well also gives about how the attenuation spreads over the frequency range of the signal changes as a result of changing cable lengths. Therefore, the reference signal to be inserted contains both a Low frequency component as well as a high frequency component, so that at the receiving end of the cable 10 the relative attenuation · can be effectively displayed over the frequency range of the transmitted signal. When the transferred Signal is a composite television signal that contains both deflection synchronous components and color synchronous components (burst) contains, then these components that normally occur during the blanking interval and a frequency of 15,750 Hz or 3.58 MHz (for the USA television standard), can be used with advantage as a reference signal. If the transmitted signal does not have horizontal sync components and does not contain any color synchronous components, then suitable signal components of a similar frequency position can be used as the reference signal inserted. As described above in connection with the characteristics of the cable 10, leave it The attenuation losses can easily be reduced with the help of this two-part reference signal, one low-frequency and one

- 6 809839/0946

contains high-frequency part, voice parts.

^{FIG. 2a shows a typical horizontal blanking interval} with a horizontal sync pulse of amplitude "a", which occurs in the time span "fc / i- ^ erscneiiri; j ^xm ^ a color sync pulse or" burst "of amplitude" b ", which occurs in the time span t ^ - 2a, when it is fed to the input end of the cable 10, experiences such an attenuation in the course of its transmission that it appears at the receiving end of the cable 10 in the form shown in FIG The shape shown there has the low-frequency component appearing during the period% * - ^ 2 ^with an only slightly reduced amplitude "a ^r " as a result of ohmic losses and a rounded leading edge as a result of dielectric losses due to the length of the cable; which occurs during the period t The high-frequency component appearing has a considerably "reduced amplitude" b ¹ ", this reduction being almost entirely due to the dielectric losses in the cable and is proportional to the length of the cable.

According to the invention, the difference or the ratio taken between the amplitudes of the low-frequency and high-frequency components of the reference signal, the amount of cable attenuation in the attenuation of the high-frequency component relative to the low-frequency component to determine. This attenuation ratio is an actual measure of the length of the cable over which the signal is transmitted will.

As described above, the attenuated incoming video signal is fed to the input of stage 28, which in itself known way the horizontal syachron component and the Burst component separates and generates a load signal, which indicates the temporal occurrence of the reference signals.

- 7 309839/0948

The strobe pulses supplied by stage 28 are applied to an input of a gated detector 30 and also fed to a keyed feedback clamp circuit 22 coupled to the output amplifier, to ensure that the keying of the attenuated components of the reference signal only during the desired Period of the blanking interval takes place. The other input of the keyed detector 30 is to the video output terminal coupled. In operation, the video signal that runs in the main path from the video input to the video output is on two peak detectors coupled, which are located in the gated detector 30 and one for the sync signal and the other is intended for the burst. The key signals coming from the stage 28 for the reference signal key respective peak detectors to obtain a direct current or direct voltage value at the output of the gated detector 30 to deliver, which is characteristic of the amplitude ratio of the synchronous signal level compared to the burst level at Video output is. The output of the detector 30 is connected to the input terminal of an amplifier 32, the output of which leads via a filter 36 to the control input Y of the multiplier circuit 24-. Venn is the DC output value of the detector 30 is essentially equal to zero, then this means that the two components of the reference signal (i.e. the synchronous component and the burst component) have not been attenuated, which corresponds to a cable length of zero. In this case, the output amplifier 18 is not supplied with a complementary correction signal.

As the length of the cable increases, the amplitude of the high frequency component (i.e. the burst) of the Reference signal relative to the low-frequency component (synchronous signal) of the reference signal. This relative The amplitude difference results in a DC level at the output of the gated detector 30, which is the amplitude difference

809839/09 46

indicates the result of the attenuation of the cable transmitted reference signals results. The DC output level of the detector 30, which changes with the cable length, is so once during each television line on the brought up to date and automatically adjusts the control voltage at the. Y input of the multiplier circuit 24- to a correction signal in the form of a "complementary" signal add so that the low-frequency component (synchronous signal) and the high-frequency component (burst) of the reference signal are brought back to their original values as at the input end of the cable 10.

The network 26 is typically expected for the largest Cable length (i.e. for about 300 meters), and the multiplier circuit 24 thus automatically provides that Correct corrective measure for cable lengths from Hull to 300 meters. The relatively high correction factor used by the high-frequency increase network 26 to compensate for the cable attenuation must be provided, can be further linearized in the values of the middle range by adding an ohmic feedback or a combined reactive and ohmic feedback as shown by a Linearxtatsnetzwerk 34 provides between the output port of the output amplifier and the input terminal of the traditionally designed high-frequency boost circuit is switched.

- 9 809839/0946

Claims (3)

Claims / 1.! SchaltSan · Order for the automatic equalization of Sig-V signals that are transmitted via a cable and that amplitude and frequency response losses have suffered, with a means to enter the signals transmitted by the cable Reference signal with low and high frequency components insert whose amplitudes change relative to one another as a result of transmission losses, and with an on summing = circuit responding to the signals transmitted by the cable, characterized by: a signal processing device coupled to said cable signals Means (26) for obtaining a correction signal derived from the cable signals; one coupled to the summing circuit (14-22) Detector arrangement (30) for generating a control signal, which is the relative amplitude difference between is proportional to the low-frequency and high-frequency components of the reference signal; one on the correction signal and one on the control signal responsive multiplier circuit (24) which couples a determined by the control signal amount of the correction signal to the summing circuit to the To restore the amplitude of the output signal «, 2. A circuit arrangement according to claim 1 ₃ characterized in that the transmitted _s through the cable signals are a composite video signal and that the reference signal is inserted into the blanking interval of the video signal _o - 10 - 809839/094 3. Circuit arrangement according to. Claim 2, characterized; that the reference signal from horizontal sync signals and There is color sync signals of the composite video signal. 809839/0946